A study on blast wave diffractions and the dynamics of associated vortices inside different grooves kept at various lateral distances from the shock tube

IF 2.5 3区 工程技术 Q2 MECHANICS
Senthilkumar Subramanian , Murugan Thangadurai , Konstantinos Kontis
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Abstract

Diffraction is a fundamental phenomenon that occurs when blast or shock waves pass over sudden discontinuous surfaces. It generates a complex flow field consisting of diffracted waves, expansion waves, slipstream, contact surface, and an unstable shear layer, in addition to emitting acoustic waves. In this study, we investigated the diffraction of a blast wave passing over a series of grooved structures with different aspect ratios and geometrical shapes (rectangular, circular, and triangular) using high-speed shadowgraph images. The blast wave Mach number considered in our investigation is 1.34. The grooves feature leading-edge geometrical variations such as rectangular, circular arc, and wedge shapes positioned at various lateral locations from the exit of the shock tube. The aspect ratios of the rectangular grooves vary from 0.33, 0.5, and 0.67. The circular and triangular grooves have an aspect ratio of 0.33. The trajectories and velocities of the primary vortex are calculated by tracking the location of the vortex in the shadowgraph images. Our observations revealed that a large portion of the incident blast wave is abducted inside the groove as the aspect ratio increases in rectangular grooves, resulting in better attenuation of the blast wave. The grooves, which have circular shapes, produced weaker diffraction, which resulted in delayed and weak primary vortex. The triangular grooves produced the strongest primary vortex and have the highest attenuation characteristics among other grooves. The strength and trajectory of the primary vortex formed over the grooves strongly depend on the aspect ratio and the curvature of the leading edge for a given Mach number. Vortices generated from rectangular and triangular grooves exhibit considerable strength and longevity.

关于冲击波衍射以及与冲击管保持不同横向距离的不同凹槽内相关涡流的动力学研究
衍射是爆炸波或冲击波经过突然出现的不连续表面时产生的一种基本现象。除了发射声波之外,它还会产生由衍射波、膨胀波、滑流、接触面和不稳定剪切层组成的复杂流场。在本研究中,我们使用高速阴影图图像研究了经过一系列不同长宽比和几何形状(矩形、圆形和三角形)沟槽结构的冲击波的衍射。研究中考虑的冲击波马赫数为 1.34。凹槽的前缘几何形状各不相同,如矩形、圆弧形和楔形,位于冲击管出口的不同横向位置。矩形凹槽的长宽比分别为 0.33、0.5 和 0.67。圆形和三角形凹槽的长宽比为 0.33。主涡流的轨迹和速度是通过跟踪阴影图图像中涡流的位置计算出来的。我们的观察结果表明,随着矩形凹槽长宽比的增加,大部分入射爆炸波被卷入凹槽内部,从而使爆炸波得到更好的衰减。圆形凹槽产生的衍射较弱,导致初级涡旋延迟且较弱。在其他凹槽中,三角形凹槽产生的原生涡旋最强,衰减特性也最高。在给定的马赫数下,凹槽上形成的初级涡旋的强度和轨迹与前缘的长宽比和曲率密切相关。矩形和三角形凹槽产生的涡流具有相当高的强度和寿命。
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来源期刊
CiteScore
5.90
自引率
3.80%
发文量
127
审稿时长
58 days
期刊介绍: The European Journal of Mechanics - B/Fluids publishes papers in all fields of fluid mechanics. Although investigations in well-established areas are within the scope of the journal, recent developments and innovative ideas are particularly welcome. Theoretical, computational and experimental papers are equally welcome. Mathematical methods, be they deterministic or stochastic, analytical or numerical, will be accepted provided they serve to clarify some identifiable problems in fluid mechanics, and provided the significance of results is explained. Similarly, experimental papers must add physical insight in to the understanding of fluid mechanics.
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